The multiaxial and uniaxial creep ductility of type 304 steel as a function of stress and strain rate

Materials at High Temperatures

Volumn 21, Issue 1, 2004, Pages 47-52

  Spindler, M W ^a  

^a BRITISH ENERGY GENERATION LTD   (United Kingdom)

Author keywords

Multiaxial and uniaxial creep ductility; Stress and strain rate; Type 304 steel

Indexed keywords

AXIAL FLOW; BENDING (DEFORMATION); CAVITATION CORROSION; CRACKS; CREEP TESTING; DUCTILITY; EXHAUST SYSTEMS (ENGINE); GRAIN BOUNDARIES; HIGH TEMPERATURE EFFECTS; STEEL METALLURGY; STRESS CORROSION CRACKING; THERMAL CONDUCTIVITY; TORSIONAL STRESS;

CREEP DAMAGE; MULTIAXIAL AND UNIAXIAL CREEP DUCTILITY; STRESS AND STRAIN RATE; TYPE-304 STEEL;

STEEL;

EID: 2542543455     PISSN: 09603409     EISSN: None     Source Type: Journal    
DOI: 10.3184/096034004782750023     Document Type: Conference Paper

References (16)

1. R5 (2001). Assessment Procedure for the High Temperature Response of Structures Issue 3, British Energy, Gloucester, UK.
2. M W Spindler (1994). The Multiaxial Creep of Austenitic Stainless Steels, Nuclear Electric Report TIGM/REP/0014/94.
3. M W Spinaler, R Haies and R P Skelton (2001). The Multiaxial Creep Ductility of an Ex-Service Type 316H Stainless Steel, Proc. 9th Int. Conf. on Creep & Fracture of Engineering Materials & Strurctures, ed. J D Parker, IOM London, UK.
4. M W Spindler (2004). The Multiaxial Creep Ductility of Austenitic Stainless Steel, Accepted by Fatigue Fract. Engng. Mater. Struct.
5. M W Spindler (2004). The Prediction of Creep Damage in Type 347 Weld Metal, Submitted to Int. J. Press. Vess. Piping.
6. R L Huddleston (1985). An Improved Multiaxial Creep Rupture Strength Criterion, ASME J. Press. Vess. Tech., 107, 421-429.
7. D Hull and D E Rimmer (1959). The Growth of Grain Boundary Voids Under Stress, Phil. Mag., 4, 673-687.
8. R Hales (1994). The Role of Cavity Growth Mechanisms in Determining Creep-Rupture under Multiaxial Stresses, Fatigue. Fract. Engng. Mater. Struct., 17, 579-291.
9. W Beere and M V Speight (1978). Creep Cavitation by Vacancy Diffusion in Plastically Deforming Solid, Metal Sci., 12, 172-176.
10. N G Needham and T Gladman (1980). Nucleation and Growth of Creep Cavities in a Type 347 Steel. Metal Sci., 14, 64-73.
11. J R Rice and D M Tracey (1969). On Ductile Enlargement of Voids in Triaxial Stress Fields, J. Mech. Phys. Solids, 17, 201-217.
12. K Hellan (1975). An Approximate Study of Void Expansion by Ductility or Creep, Int. J. Mech. Sci., 17, 369-374.
13. A C F Cocks and M F Ashby (1980). Intergranular Fracture During Power-Law Creep Under Multiaxial Stresses, Metal Sci., 14, 395-402.
14. B F Dyson (1979). Constrained Cavity Growth, its use in Quantifying Recent Creep Fracture Results, Can. Met. Quart., 18, 31-38.
15. R W Swindeman and C W Houck, (1984) Metallographic Examination of Type 304 Stainless Steel (Heal 9T2796) Tested in High-Temperature Uniaxial and Multiaxial Experiments, ORNL-6013.
16. M Murata, H Tanaka, F Abe and H Trie, (2001) Assessment of Material Degradation Based on Mircostructural Evolution in Type 304H Stainless Steel During Long-Tenu Creep, Proc. of Creep 7, JSME, Tokyo, Japan.